Senescence is the process that marks the end of a leaf's lifespan. As it progresses, the massive macromolecular catabolism dismantles the chloroplasts and, consequently, decreases the photosynthetic capacity of these organs. Thus, senescence manipulation is a strategy to improve plant yield by extending the leaf's photosynthetically active window of time. However, it remains to be addressed if this approach can improve fleshy fruit production and nutritional quality. One way to delay senescence initiation is by regulating key transcription factors (TFs) involved in triggering this process, such as the NAC TF ORESARA1 (ORE1). Here, three senescence-related NAC TFs from tomato (Solanum lycopersicum) were identified, namely SlORE1S02, SlORE1S03, and SlORE1S06. All three genes were shown to be responsive to senescence-inducing stimuli and posttranscriptionally regulated by the microRNA miR164. Moreover, the encoded proteins interacted physically with the chloroplast maintenance-related TF SlGLKs. This characterization led to the selection of a putative tomato ORE1 as target gene for RNA interference knockdown. Transgenic lines showed delayed senescence and enhanced carbon assimilation that, ultimately, increased the number of fruits and their total soluble solid content. Additionally, the fruit nutraceutical composition was enhanced. In conclusion, these data provide robust evidence that the manipulation of leaf senescence is an effective strategy for yield improvement in fleshy fruit-bearing species.
Fruit-localized phytochromes and their downstream signaling cascades not only modulate chloroplast biogenesis in immature tomato fruits but also regulate sugar and carotenoid accumulation, two essential features of tomato fruit quality.
Phytochomes and plant hormones have been emerging as important regulators of fleshy fruit biology and quality traits; however, the relevance of phytochrome-hormonal signaling crosstalk in controlling fruit development and metabolism remains elusive. Here, we show that the deficiency in phytochrome chromophore phytochromobilin (PΦB) biosynthesis inhibits sugar accumulation in tomato (Solanum lycopersicum) fruits by transcriptionally downregulating sink- and starch biosynthesis-related enzymes, such as cell-wall invertases, sucrose transporters and ADP-glucose pyrophosphorylases. PΦB deficiency was also shown to repress fruit chloroplast biogenesis, which implicates more limited production of photoassimilates via fruit photosynthesis. Genetic and physiological data revealed the involvement of auxins and cytokinins in mediating the negative impact of PΦB deficiency on fruit sink strength and chloroplast formation. PΦB deficiency was shown to transcriptionally repress type-A TOMATO RESPONSE REGULATORs and AUXIN RESPONSE FACTORs both in pericarp and columella, suggesting active phytochrome-hormonal signaling crosstalk in these tissues. Data also revealed that PΦB deficiency influences fruit ripening by delaying the climacteric rise in ethylene production and signaling. Altogether, the data uncover the impact of phytochromobilin deficiency in fine-tuning sugar metabolism, chloroplast formation and the timing of fruit ripening and also reveal a link between auxins, cytokinins and phytochromes in regulating sugar import and accumulation in fruits.
The transition from etiolated to green seedlings involves the conversion of etioplasts into mature chloroplasts via a multifaceted, light-driven process comprising multiple, tightly coordinated signaling networks. Here, we demonstrate that light-induced greening and chloroplast differentiation in tomato (Solanum lycopersicum) seedlings are mediated by an intricate cross talk among phytochromes, nitric oxide (NO), ethylene, and auxins. Genetic and pharmacological evidence indicated that either endogenously produced or exogenously applied NO promotes seedling greening by repressing ethylene biosynthesis and inducing auxin accumulation in tomato cotyledons. Analysis performed in hormonal tomato mutants also demonstrated that NO production itself is negatively and positively regulated by ethylene and auxins, respectively. Representing a major biosynthetic source of NO in tomato cotyledons, nitrate reductase was shown to be under strict control of both phytochrome and hormonal signals. A close NO-phytochrome interaction was revealed by the almost complete recovery of the etiolated phenotype of red light-grown seedlings of the tomato phytochrome-deficient aurea mutant upon NO fumigation. In this mutant, NO supplementation induced cotyledon greening, chloroplast differentiation, and hormonal and gene expression alterations similar to those detected in light-exposed wild-type seedlings. NO negatively impacted the transcript accumulation of genes encoding phytochromes, photomorphogenesis-repressor factors, and plastid division proteins, revealing that this free radical can mimic transcriptional changes typically triggered by phytochrome-dependent light perception. Therefore, our data indicate that negative and positive regulatory feedback loops orchestrate ethylene-NO and auxin-NO interactions, respectively, during the conversion of colorless etiolated seedlings into green, photosynthetically competent young plants.
HighlightPhytol kinase plays a key role in the regulation of isoprenoid metabolism in an organ-specific manner.
Although biochemically related, C 4 and crassulacean acid metabolism (CAM) systems are expected to be incompatible. However, Portulaca species, including P. oleracea, operate C 4 and CAM within a single leaf, and the mechanisms behind this unique photosynthetic arrangement remain largely unknown.Here, we employed RNA-seq to identify candidate genes involved exclusively or shared by C 4 or CAM, and provided an in-depth characterization of their transcript abundance patterns during the drought-induced photosynthetic transitions in P. oleracea. Data revealed fewer candidate CAM-specific genes than those recruited to function in C 4 . The putative CAMspecific genes were predominantly involved in night-time primary carboxylation reactions and malate movement across the tonoplast. Analysis of gene transcript-abundance regulation and photosynthetic physiology indicated that C 4 and CAM coexist within a single P. oleracea leaf under mild drought conditions. Developmental and environmental cues were shown to regulate CAM expression in stems, whereas the shift from C 4 to C 4 -CAM hybrid photosynthesis in leaves was strictly under environmental control. Moreover, efficient starch turnover was identified as part of the metabolic adjustments required for CAM operation in both organs.These findings provide insights into C 4 /CAM connectivity and compatibility, contributing to a deeper understanding of alternative ways to engineer CAM into C 4 crop species.
-(Articulated anastomosing laticifers -new records for Apocynaceae). Laticifer presence is universal in Apocynaceae, in the classic literature the type described for this family is the non-articulated. Later researches have proved the occurrence of articulated laticifers only in four species, giving rise to controversies on their origin. The results obtained in our studies differ from those reported for most species of this family. In both Aspidosperma australe Müll. Arg. (Rauvolfioideae) and Blepharodon bicuspidatum Fourn. (Asclepiadoideae), the laticifers are of the articulated anastomosing type because they are formed by adding cells with rapidly dissolving transverse walls. Laticifers originate from ground meristem and/or procambium and form a branched system, they are in secretory phase since the early stages of formation in different organs, releasing latex only when the plant is damaged. The laticifer walls are exclusively pectic-cellulosic and their chemical characteristics probably change during their development. Vegetative organ laticifers occur in all stem and leaf tissues, except epidermis and medullary parenchyma of A. australe. In the flower, laticifers are found in all floral organs, except in the medullary parenchyma of the pedicel of A. australe and in the ovules of both species. The presence of the same type of laticifer in these two genera, which represent the most divergent subfamilies within the Apocynaceae corroborates the current circumscription of this family. The latex has protective function, allowing the species of this family to succeed in different environments.Key words -anatomy, Apocynaceae, articulated laticifers, distribution, ontogeny RESUMO -(Laticíferos articulados anastomosados -novos registros para Apocynaceae). A presença de laticíferos é universal nas Apocynaceae e o tipo descrito nas obras clássicas de revisão para esta família é o não articulado. Pesquisas posteriores provaram a ocorrência de laticíferos articulados apenas em quatro espécies, suscitando controvérsias quanto à sua origem. Os resultados obtidos em nossos estudos divergem dos já publicados para a maioria das espécies da família. Tanto em Aspidosperma australe Müll. Arg. (Rauvolfioideae) quanto em Blepharodon bicuspidatum Fourn. (Asclepiadoideae), os laticíferos são articulados anastomosados e formados por adição de células, cujas paredes transversais dissolvem-se rapidamente. Eles originam-se a partir do meristema fundamental e/ou procâmbio, já estão em fase secretora desde o início de sua formação nos diferentes órgãos, constituindo um sistema ramificado e só liberam o látex se a planta for injuriada. As paredes dos laticíferos são exclusivamente pectocelulósicas e suas características químicas provavelmente se alteram durante o seu desenvolvimento. Os laticíferos dos órgãos vegetativos ocorrem em todos os tecidos do caule e da folha, com exceção da epiderme e do parênquima medular de A. australe. Na flor, eles são encontrados em todas as peças florais, exceto no parênquima medular do pedicelo de...
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